freebsd-skq/lib/libmp/mpasbn.c
Dima Dorfman 656c5bc76b This is the traditional BSD libmp interface implemented in terms of
the OpenSSL BIGNUM interface.  It is provided for compatibility only
and should not be used in new code.
2001-07-29 08:49:15 +00:00

593 lines
13 KiB
C

/*
* Copyright (c) 2001 Dima Dorfman.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
/*
* This is the traditional Berkeley MP library implemented in terms of
* the OpenSSL BIGNUM library. It was written to replace libgmp, and
* is meant to be as compatible with the latter as feasible.
*
* There seems to be a lack of documentation for the Berkeley MP
* interface. All I could find was libgmp documentation (which didn't
* talk about the semantics of the functions) and an old SunOS 4.1
* manual page from 1989. The latter wasn't very detailed, either,
* but at least described what the function's arguments were. In
* general the interface seems to be archaic, somewhat poorly
* designed, and poorly, if at all, documented. It is considered
* harmful.
*
* Miscellaneous notes on this implementation:
*
* - The SunOS manual page mentioned above indicates that if an error
* occurs, the library should "produce messages and core images."
* Given that most of the functions don't have return values (and
* thus no sane way of alerting the caller to an error), this seems
* reasonable. The MPERR and MPERRX macros call warn and warnx,
* respectively, then abort().
*
* - All the functions which take an argument to be "filled in"
* assume that the argument has been initialized by one of the *tom()
* routines before being passed to it. I never saw this documented
* anywhere, but this seems to be consistent with the way this
* library is used.
*
* - msqrt() is the only routine which had to be implemented which
* doesn't have a close counterpart in the OpenSSL BIGNUM library.
* It was implemented by hand using Newton's recursive formula.
* Doing it this way, although more error-prone, has the positive
* sideaffect of testing a lot of other functions; if msqrt()
* produces the correct results, most of the other routines will as
* well.
*
* - Internal-use-only routines (i.e., those defined here statically
* and not in mp.h) have an underscore prepended to their name (this
* is more for aesthetical reasons than technical). All such
* routines take an extra argument, 'msg', that denotes what they
* should call themselves in an error message. This is so a user
* doesn't get an error message from a function they didn't call.
*/
#ifndef lint
static const char rcsid[] =
"$FreeBSD$";
#endif /* not lint */
#include <ctype.h>
#include <err.h>
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <openssl/bn.h>
#include <openssl/crypto.h>
#include <openssl/err.h>
#include "mp.h"
#define MPERR(s) do { warn s; abort(); } while (0)
#define MPERRX(s) do { warnx s; abort(); } while (0)
#define BN_ERRCHECK(msg, expr) do { \
if (!(expr)) _bnerr(msg); \
} while (0)
static void _bnerr(const char *);
static MINT *_dtom(const char *, const char *);
static MINT *_itom(const char *, short);
static void _madd(const char *, const MINT *, const MINT *, MINT *);
static int _mcmpa(const char *, const MINT *, const MINT *);
static void _mdiv(const char *, const MINT *, const MINT *, MINT *, MINT *);
static void _mfree(const char *, MINT *);
static void _moveb(const char *, const BIGNUM *, MINT *);
static void _movem(const char *, const MINT *, MINT *);
static void _msub(const char *, const MINT *, const MINT *, MINT *);
static char *_mtod(const char *, const MINT *);
static char *_mtox(const char *, const MINT *);
static void _mult(const char *, const MINT *, const MINT *, MINT *);
static void _sdiv(const char *, const MINT *, short, MINT *, short *);
static MINT *_xtom(const char *, const char *);
/*
* Report an error from one of the BN_* functions using MPERRX.
*/
static void
_bnerr(const char *msg)
{
ERR_load_crypto_strings();
MPERRX(("%s: %s", msg, ERR_reason_error_string(ERR_get_error())));
}
/*
* Convert a decimal string to an MINT.
*/
static MINT *
_dtom(const char *msg, const char *s)
{
MINT *mp;
mp = malloc(sizeof(*mp));
if (mp == NULL)
MPERR(("%s", msg));
mp->bn = BN_new();
if (mp->bn == NULL)
_bnerr(msg);
BN_ERRCHECK(msg, BN_dec2bn(&mp->bn, s));
return (mp);
}
/*
* Compute the greatest common divisor of mp1 and mp2; result goes in rmp.
*/
void
gcd(const MINT *mp1, const MINT *mp2, MINT *rmp)
{
BIGNUM b;
BN_CTX c;
BN_CTX_init(&c);
BN_init(&b);
BN_ERRCHECK("gcd", BN_gcd(&b, mp1->bn, mp2->bn, &c));
_moveb("gcd", &b, rmp);
BN_free(&b);
BN_CTX_free(&c);
}
/*
* Make an MINT out of a short integer. Return value must be mfree()'d.
*/
static MINT *
_itom(const char *msg, short n)
{
MINT *mp;
char *s;
asprintf(&s, "%x", n);
if (s == NULL)
MPERR(("%s", msg));
mp = _xtom(msg, s);
free(s);
return (mp);
}
MINT *
itom(short n)
{
return (_itom("itom", n));
}
/*
* Compute rmp=mp1+mp2.
*/
static void
_madd(const char *msg, const MINT *mp1, const MINT *mp2, MINT *rmp)
{
BIGNUM b;
BN_init(&b);
BN_ERRCHECK(msg, BN_add(&b, mp1->bn, mp2->bn));
_moveb(msg, &b, rmp);
BN_free(&b);
}
void
madd(const MINT *mp1, const MINT *mp2, MINT *rmp)
{
_madd("madd", mp1, mp2, rmp);
}
/*
* Return -1, 0, or 1 if mp1<mp2, mp1==mp2, or mp1>mp2, respectivley.
*/
int
mcmp(const MINT *mp1, const MINT *mp2)
{
return (BN_cmp(mp1->bn, mp2->bn));
}
/*
* Same as mcmp but compares absolute values.
*/
static int
_mcmpa(const char *msg __unused, const MINT *mp1, const MINT *mp2)
{
return (BN_ucmp(mp1->bn, mp2->bn));
}
/*
* Compute qmp=nmp/dmp and rmp=nmp%dmp.
*/
static void
_mdiv(const char *msg, const MINT *nmp, const MINT *dmp, MINT *qmp, MINT *rmp)
{
BIGNUM q, r;
BN_CTX c;
BN_CTX_init(&c);
BN_init(&r);
BN_init(&q);
BN_ERRCHECK(msg, BN_div(&q, &r, nmp->bn, dmp->bn, &c));
_moveb(msg, &q, qmp);
_moveb(msg, &r, rmp);
BN_free(&q);
BN_free(&r);
BN_CTX_free(&c);
}
void
mdiv(const MINT *nmp, const MINT *dmp, MINT *qmp, MINT *rmp)
{
_mdiv("mdiv", nmp, dmp, qmp, rmp);
}
/*
* Free memory associated with an MINT.
*/
static void
_mfree(const char *msg __unused, MINT *mp)
{
BN_clear(mp->bn);
BN_free(mp->bn);
free(mp);
}
void
mfree(MINT *mp)
{
_mfree("mfree", mp);
}
/*
* Read an integer from standard input and stick the result in mp.
* The input is treated to be in base 10. This must be the silliest
* API in existence; why can't the program read in a string and call
* xtom()? (Or if base 10 is desires, perhaps dtom() could be
* exported.)
*/
void
min(MINT *mp)
{
MINT *rmp;
char *line, *nline;
size_t linelen;
line = fgetln(stdin, &linelen);
if (line == NULL)
MPERR(("min"));
nline = malloc(linelen);
if (nline == NULL)
MPERR(("min"));
strncpy(nline, line, linelen);
nline[linelen] = '\0';
rmp = _dtom("min", nline);
_movem("min", rmp, mp);
_mfree("min", rmp);
free(nline);
}
/*
* Print the value of mp to standard output in base 10. See blurb
* above min() for why this is so useless.
*/
void
mout(const MINT *mp)
{
char *s;
s = _mtod("mout", mp);
printf("%s", s);
free(s);
}
/*
* Set the value of tmp to the value of smp (i.e., tmp=smp).
*/
void
move(const MINT *smp, MINT *tmp)
{
_movem("move", smp, tmp);
}
/*
* Internal routine to set the value of tmp to that of sbp.
*/
static void
_moveb(const char *msg, const BIGNUM *sbp, MINT *tmp)
{
BN_ERRCHECK(msg, BN_copy(tmp->bn, sbp));
}
/*
* Internal routine to set the value of tmp to that of smp.
*/
static void
_movem(const char *msg, const MINT *smp, MINT *tmp)
{
BN_ERRCHECK(msg, BN_copy(tmp->bn, smp->bn));
}
/*
* Compute the square root of nmp and put the result in xmp. The
* remainder goes in rmp. Should satisfy: rmp=nmp-(xmp*xmp).
*
* Note that the OpenSSL BIGNUM library does not have a square root
* function, so this had to be implemented by hand using Newton's
* recursive formula:
*
* x = (x + (n / x)) / 2
*
* where x is the square root of the positive number n. In the
* beginning, x should be a reasonable guess, but the value 1,
* although suboptimal, works, too; this is that is used below.
*/
void
msqrt(const MINT *nmp, MINT *xmp, MINT *rmp)
{
MINT *tolerance;
MINT *ox, *x;
MINT *z1, *z2, *z3;
short i;
tolerance = _itom("msqrt", 1);
x = _itom("msqrt", 1);
ox = _itom("msqrt", 0);
z1 = _itom("msqrt", 0);
z2 = _itom("msqrt", 0);
z3 = _itom("msqrt", 0);
do {
_movem("msqrt", x, ox);
_mdiv("msqrt", nmp, x, z1, z2);
_madd("msqrt", x, z1, z2);
_sdiv("msqrt", z2, 2, x, &i);
_msub("msqrt", ox, x, z3);
} while (_mcmpa("msqrt", z3, tolerance) == 1);
_movem("msqrt", x, xmp);
_mult("msqrt", x, x, z1);
_msub("msqrt", nmp, z1, z2);
_movem("msqrt", z2, rmp);
_mfree("msqrt", tolerance);
_mfree("msqrt", ox);
_mfree("msqrt", x);
_mfree("msqrt", z1);
_mfree("msqrt", z2);
_mfree("msqrt", z3);
}
/*
* Compute rmp=mp1-mp2.
*/
static void
_msub(const char *msg, const MINT *mp1, const MINT *mp2, MINT *rmp)
{
BIGNUM b;
BN_init(&b);
BN_ERRCHECK(msg, BN_sub(&b, mp1->bn, mp2->bn));
_moveb(msg, &b, rmp);
BN_free(&b);
}
void
msub(const MINT *mp1, const MINT *mp2, MINT *rmp)
{
_msub("msub", mp1, mp2, rmp);
}
/*
* Return a decimal representation of mp. Return value must be
* free()'d.
*/
static char *
_mtod(const char *msg, const MINT *mp)
{
char *s, *s2;
s = BN_bn2dec(mp->bn);
if (s == NULL)
_bnerr(msg);
asprintf(&s2, "%s", s);
if (s2 == NULL)
MPERR(("%s", msg));
OPENSSL_free(s);
return (s2);
}
/*
* Return a hexadecimal representation of mp. Return value must be
* free()'d.
*/
static char *
_mtox(const char *msg, const MINT *mp)
{
char *p, *s, *s2;
int len;
s = BN_bn2hex(mp->bn);
if (s == NULL)
_bnerr(msg);
asprintf(&s2, "%s", s);
if (s2 == NULL)
MPERR(("%s", msg));
OPENSSL_free(s);
/*
* This is a kludge for libgmp compatibility. The latter's
* implementation of this function returns lower-case letters,
* but BN_bn2hex returns upper-case. Some programs (e.g.,
* newkey(1)) are sensitive to this. Although it's probably
* their fault, it's nice to be compatible.
*/
len = strlen(s2);
for (p = s2; p < s2 + len; p++)
*p = tolower(*p);
return (s2);
}
char *
mtox(const MINT *mp)
{
return (_mtox("mtox", mp));
}
/*
* Compute rmp=mp1*mp2.
*/
static void
_mult(const char *msg, const MINT *mp1, const MINT *mp2, MINT *rmp)
{
BIGNUM b;
BN_CTX c;
BN_CTX_init(&c);
BN_init(&b);
BN_ERRCHECK(msg, BN_mul(&b, mp1->bn, mp2->bn, &c));
_moveb(msg, &b, rmp);
BN_free(&b);
BN_CTX_free(&c);
}
void
mult(const MINT *mp1, const MINT *mp2, MINT *rmp)
{
_mult("mult", mp1, mp2, rmp);
}
/*
* Compute rmp=(bmp^emp)mod mmp. (Note that here and above rpow() '^'
* means 'raise to power', not 'bitwise XOR'.)
*/
void
pow(const MINT *bmp, const MINT *emp, const MINT *mmp, MINT *rmp)
{
BIGNUM b;
BN_CTX c;
BN_CTX_init(&c);
BN_init(&b);
BN_ERRCHECK("pow", BN_mod_exp(&b, bmp->bn, emp->bn, mmp->bn, &c));
_moveb("pow", &b, rmp);
BN_free(&b);
BN_CTX_free(&c);
}
/*
* Compute rmp=bmp^e. (See note above pow().)
*/
void
rpow(const MINT *bmp, short e, MINT *rmp)
{
MINT *emp;
BIGNUM b;
BN_CTX c;
BN_CTX_init(&c);
BN_init(&b);
emp = _itom("rpow", e);
BN_ERRCHECK("rpow", BN_exp(&b, bmp->bn, emp->bn, &c));
_moveb("rpow", &b, rmp);
_mfree("rpow", emp);
BN_free(&b);
BN_CTX_free(&c);
}
/*
* Compute qmp=nmp/d and ro=nmp%d.
*/
static void
_sdiv(const char *msg, const MINT *nmp, short d, MINT *qmp, short *ro)
{
MINT *dmp, *rmp;
BIGNUM q, r;
BN_CTX c;
char *s;
BN_CTX_init(&c);
BN_init(&q);
BN_init(&r);
dmp = _itom(msg, d);
rmp = _itom(msg, 0);
BN_ERRCHECK(msg, BN_div(&q, &r, nmp->bn, dmp->bn, &c));
_moveb(msg, &q, qmp);
_moveb(msg, &r, rmp);
s = _mtox(msg, rmp);
errno = 0;
*ro = strtol(s, NULL, 16);
if (errno != 0)
MPERR(("%s underflow or overflow", msg));
free(s);
_mfree(msg, dmp);
_mfree(msg, rmp);
BN_free(&r);
BN_free(&q);
BN_CTX_free(&c);
}
void
sdiv(const MINT *nmp, short d, MINT *qmp, short *ro)
{
_sdiv("sdiv", nmp, d, qmp, ro);
}
/*
* Convert a hexadecimal string to an MINT.
*/
static MINT *
_xtom(const char *msg, const char *s)
{
MINT *mp;
mp = malloc(sizeof(*mp));
if (mp == NULL)
MPERR(("%s", msg));
mp->bn = BN_new();
if (mp->bn == NULL)
_bnerr(msg);
BN_ERRCHECK(msg, BN_hex2bn(&mp->bn, s));
return (mp);
}
MINT *
xtom(const char *s)
{
return (_xtom("xtom", s));
}